The FuGas 2.3 Framework for Atmosphere-Ocean Coupling: Comparing Algorithms for the Estimation of Solubilities and Gas Fluxes

0492154 - ÚI 2019 RIV CH eng J - Článek v odborném periodiku
Vieira, V. - Juruš, Pavel - Clementi, E. - Mateus, M.
The FuGas 2.3 Framework for Atmosphere-Ocean Coupling: Comparing Algorithms for the Estimation of Solubilities and Gas Fluxes.
Atmosphere. Roč. 9, č. 8 (2018), č. článku 310. E-ISSN 2073-4433
Institucionální podpora: RVO:67985807
Klíčová slova: solubility * transfer velocity * Henry constant
Obor OECD: Meteorology and atmospheric sciences
Impakt faktor: 2.046, rok: 2018

Accurate estimates of the atmosphere–ocean fluxes of greenhouse gases and dimethyl sulphide (DMS) have great importance in climate change models. A significant part of these fluxes occur at the coastal ocean which, although much smaller than the open ocean, have more heterogeneous conditions. Hence, Earth System Modelling (ESM) requires representing the oceans at finer resolutions which, in turn, requires better descriptions of the chemical, physical and biological processes. The standard formulations for the solubilities and gas transfer velocities across air–water surfaces are 36 and 24 years old, and new alternatives have emerged. We have developed a framework combining the related geophysical processes and choosing from alternative formulations with different degrees of complexity. The framework was tested with fine resolution data from the European coastal ocean. Although the benchmark and alternative solubility formulations generally agreed well, their minor divergences yielded differences of up to 5.8% for CH4 dissolved at the ocean surface. The transfer velocities differ strongly (often more than 100%), a consequence of the benchmark empirical wind-based formulation disregarding significant factors that were included in the alternatives. We conclude that ESM requires more comprehensive simulations of atmosphere–ocean interactions, and that further calibration and validation is needed for the formulations to be able to reproduce it. We propose this framework as a basis to update with formulations for processes specific to the air–water boundary, such as the presence of surfactants, rain, the hydration reaction or biological activity.
Trvalý link: http://hdl.handle.net/11104/0285713